Engineering Applications of the Arbitrary Polygon Hybrid Stress Finite Element Method

TANG Li; FANG Bohao; GUO Ran

doi:10.21656/1000-0887.460165

Volume 46 Issue 10

Oct. 2025

Turn off MathJax

Article Contents

Article Navigation > Applied Mathematics and Mechanics > 2025 > 46(10): 1285-1294

TANG Li, FANG Bohao, GUO Ran. Engineering Applications of the Arbitrary Polygon Hybrid Stress Finite Element Method[J]. Applied Mathematics and Mechanics, 2025, 46(10): 1285-1294. doi: 10.21656/1000-0887.460165

Citation:

PDF( 5258 KB)

Engineering Applications of the Arbitrary Polygon Hybrid Stress Finite Element Method

doi: 10.21656/1000-0887.460165

Faculty of Civil Engineering and Mechanics, Kunming University of Science and Technology, Kunming 650500, P.R.China

Funds:

The National Science Foundation of China(2024YFC3809503)

Received Date: 2025-09-15
Rev Recd Date: 2025-09-18

Available Online: 2025-11-13

Abstract

Abstract

With the continuous expansion and increasing complexity of major engineering projects in China, the safety analysis of engineering structures has been increasingly dependent on numerical methods. Traditional finite element methods have certain limitations in complex geometries, such as strong mesh dependency and low calculation efficiency. The polygonal hybrid stress finite element method (PHSEM), based on the principle of minimum complementary energy and the introduced higher-order stress fields, is capable of accurately capturing stress distributions with fewer elements while improving calculation efficiency. A multi-material slope model considering gravity was established for the left-bank accumulation slope at the Xiluodu Hydropower Station, to verify the applicability and effectiveness of the PHSEM under complex geological conditions. Four representative slope cross sections were selected for stress and strain calculations, and both stress and strain contours were utilized to visually reveal the differences in force distributions and potentially dangerous zones for different sections. The results demonstrate that, the PHSEM can effectively reflect the distribution patterns of slope stresses and strains, providing a reliable basis for the slope stability evaluation, the retaining structure design, and the engineering treatment schemes. Furthermore, the findings highlight the potential of the PHSEM in analyzing complex slopes and large-scale engineering structures, offering valuable references for future numerical simulations and safety assessments of similar major projects.
- arbitrary polygon,
- hybrid stress finite element,
- numerical simulation,
- high-order stress field,
- engineering application

FullText(HTML)

References(20)

References

[2]ZIENKIEWICZ O C, TAYLOR R L, ZHU J Z. The Finite Element Method[M]. 7th ed. Oxford: Butterworth-Heinemann, 2013.

潘城. 岩石动态力学特性及破裂机理的晶粒离散元研究[D]. 南京: 东南大学, 2022. (PAN Cheng. Investigations of rock dynamic properties and fracture mechanisms using grain-based discrete element method[D]. Nanjing: Southeast University, 2022. (in Chinese))

[3]COOK R D. Concepts and Applications of Finite Element Analysis[M]. 4th ed. New York: John Wiley & Sons, 2007.

[4]HUTTON D V. Fundamentals of Finite Element Analysis[M]. New York: McGraw-Hill, 2003.

[5]CHAPRA S C, CANALE R P. Numerical Methods for Engineers[M]. 7th ed. New York: McGraw-Hill, 2014.

[6]BREBBIA C A, TELLES J C F, WROBEL L C. Boundary Element Techniques[M]. 2nd ed. Berlin: Springer, 2012.

[7]CUNDALL P A, STRACK O D L. A discrete numerical model for granular assemblies[J]. Géotechnique,1979,29(1): 47-65.

[8]PIAN T H H. Derivation of element stiffness matrices by assumed stress distributions[J]. AIAA Journal,1964,2(7): 1333-1336.

[9]PIAN T H H. A historical note about ‘hybrid elements’[J]. International Journal for Numerical Methods in Engineering,1978,12(5): 891-892.

[10]PIAN T H H, TONG P. Relations between incompatible displacement model and hybrid stress model[J]. International Journal for Numerical Methods in Engineering,1986,22(1): 173-181.

[11]SAETHER E. Closed-form derivation of an 8-node hexahedral element stiffness matrix by the hybrid stress method[J]. Communications in Numerical Methods in Engineering,1995,11(9): 775-787.

[12]PIAN T H H, WU C C. Hybrid and Incompatible Finite Element Methods[M]. 1st ed. Boca Raton: Chapman & Hall/CRC, 2005.

[13]魏高峰, 冯伟, 高洪芬. 基于位移插值的Voronoi单元有限元方法[J]. 应用力学学报, 2008,25(2): 342-346. (WEI Gaofeng, FENG Wei, GAO Hongfen. Voronoi cell finite element method based on displacement interpolation[J]. Chinese Journal of Applied Mechanics,2008,25(2): 342-346. (in Chinese))

[14]ZHOU P L, CEN S. A novel shape-free plane quadratic polygonal hybrid stress-function element[J]. Mathematical Problems in Engineering,2015,2015: 491325.

[15]杨锋, 郭然. 多边形应力杂交单元的接触算法研究[J]. 应用数学和力学, 2019,40(10): 1059-1070. (YANG Feng, GUO Ran. Study on contact algorithms for the polygonal hybrid stress element method[J]. Applied Mathematics and Mechanics,2019,40(10): 1059-1070. (in Chinese))

[16]WU C J, CEN S, SHANG Y. Shape-free polygonal hybrid displacement-function element method for analyses of Mindlin-Reissner plates[J]. Engineering With Computers,2021,37(3): 1975-1998.

[17]黎子君, 田静杰, 胡长浩, 等. 考虑蠕变的任意多边形杂交应力单元[J]. 重庆大学学报, 2025,48(8): 28-39. (LI Zijun, TIAN Jingjie, HU Changhao, et al. Arbitrary polygonal hybrid stress element for creep analysis in roadbed engineering[J]. Journal of Chongqing University,2025,48(8): 28-39. (in Chinese))

[18]伍文锋, 税思梅. 溪洛渡水电站左岸谷肩堆积体边坡治理和监测[J]. 水电站设计, 2013,29(4): 97-10. (WU Wenfeng, SHUI Simei. Slope treatment and monitoring of the left bank valley shoulder accumulation body at Xiluodu hydropower station[J]. Design of Hydroelectric Power Station,2013,29(4): 97-10. (in Chinese))

[19]LIU C, TIAN J, HU C, et al. Slope calculation analysis based on arbitrary polygonal hybrid stress elements considering gravity[J]. Symmetry,2025,17(2): 265.

[20]胡筱, 尤林, 赵艳. 溪洛渡水电站坝区左岸进水口上方谷肩堆积体边坡综合治理设计[J]. 水电站设计, 2011,27(3): 31-35. (HU Xiao, YOU Lin, ZHAO Yan. Comprehensive treatment design for the slope of valley shoulder accumulation above the left bank intake dam area of Xiluodu hydropower station[J]. Design of Hydroelectric Power Station,2011,27(3): 31-35. (in Chinese))

Relative Articles

Supplements(0)

Cited By

Proportional views